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Renewable Energy & Resources

Renewable energy is a form of energy derived from natural sources that are replenished at a higher rate than they are consumed. Renewable energy sources are plentiful and all around us. Sunlight and wind, for example, are such sources that are constantly being replenished. Renewables are now cheaper in most countries. Economies of scale and innovation are already resulting in renewable energies becoming the most sustainable solution environmentally but also economically in terms of low costs for keeping energy prices at affordable levels. As of today, around 20% of the world’s energy needs come from renewable energy sources.

Resources:

Solar energy
Wind energy
Hydro energy
Tidal energy
Geothermal energy
Biomass energy
Photovoltaic Technology

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Sustainable Development

Sustainable development is the necessity which is needed in the present, without compromising the ability of future generations to meet their own needs. Sustainable development is about more than just the environment. Since the dawn of industrialization, the world has seen increasingly rapid advancements in technology which has caused an accelerated pace of development beyond what the earth’s natural resources can sustain. Sustainable development mainly covers the use of renewable energy, energy security, energy pricing, energy policy, renewable energy applications and smart grid technologies. Sustainable Development has three major components: Economic growth, Environmental stewardship and Social inclusion.

Sustainable agricultural systems
Sustainable energy and environment
Waste and residue management
Smart sustainable cities
Green and clean technologies

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Global Industrial Processes and Sustainable Development:

Sustainable industrial development works to minimize its environmental footprint while maintaining economic growth, social advancement and quality of life. Sustainable industrial development ensures that resources are used conservatively and efficiently. Sustainable industrial development offers plenty of economic benefits. Technological progress is the foundation of efforts to achieve environmental objectives, such as increased resource and energy-efficiency. Without technology and innovation, industrialization will not happen, and without industrialization, development will not happen. The industry itself promotes jobs and income associated with reducing environmental impact. Improved environmental performance can also lead to increased labor productivity and product quality, contributing to a healthier economy.

Sustainable industrial development can also lower operating costs for businesses. Sustainable and efficient processes use less energy, water and materials, which can lead to significant cost savings. Perhaps the most obvious benefit of sustainable industrialization is reduced environmental impact. Sustainable industrial development works to lower greenhouse gas emissions and conserve water, energy and natural resources.

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Solar Energy

Solar energy is the most abundant of all energy resources and can even be harnessed in cloudy weather. The rate at which solar energy is intercepted by the Earth is about 10,000 times greater than the rate at which humankind consumes energy. Solar technologies can deliver heat, cooling, natural lighting, electricity, and fuels for a host of applications. Solar technologies convert sunlight into electrical energy either through photovoltaic panels or through mirrors that concentrate solar radiation. Solar panels can be of different types depending on the mechanism chosen for the use of solar energy:

Using solar thermal collectors (thermal solar energy)
Using photovoltaic solar panels (photovoltaic solar energy)
Without any external element (passive solar energy)

Types of Solar Energy:

Photovoltaic Solar Energy
Solar Thermal Energy
Concentrating Solar Power
Passive Solar Energy

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Wind Energy

Wind energy can be defined where wind is used to produce electricity by converting the kinetic energy of air in motion into electricity. In modern wind turbines, wind rotates the rotor blades, which convert kinetic energy into rotational energy. This rotational energy is transferred by a shaft which to the generator, thereby producing electrical energy. Both onshore and offshore wind still have tremendous potential for greater deployment and improvement, globally.

Types of wind energy:

Utility-Scale Wind
Offshore Wind
Distributed or Small Wind

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Hydro Energy

Hydro Energy harnesses the energy of water moving from higher to lower elevations. It can be generated from reservoirs and rivers. Reservoir hydropower plants rely on stored water in a reservoir, while run-of-river hydropower plants harness energy from the available flow of the river. Hydropower currently is the largest source of renewable energy in the electricity sector. It relies on generally stable rainfall patterns, and can be negatively impacted by climate-induced droughts or changes to ecosystems which impact rainfall patterns.

Hydro Energy emerging technologies:

Hydropower flexibility
Hydropower digitalization
Energy storage and variable speed turbines
Generators with current-controlled rotors
Novel small-scale hydropower technologies
Fish-friendly hydropower technologies

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Tidal Energy

Tidal energy is a renewable energy powered by the natural rise and fall of ocean tides and currents. Some of these technologies include turbines and paddles. Tidal currents with sufficient energy for harvesting occur when water passes through a constriction, causing the water to move faster.

Tidal Energy Generators:

Tidal streams,
Barrages,
Tidal lagoons

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Geothermal Energy

Geothermal energy utilizes the accessible thermal energy from the Earth’s interior. Heat is extracted from geothermal reservoirs using wells or other means. The technology for electricity generation from hydrothermal reservoirs is mature and reliable, and has been operating for more than 100 years. The vast majority of Earth’s heat is constantly generated by the decay of radioactive isotopes, such as potassium-40 and thorium-232. Radioactive decay is a continual process in the core. Temperatures there rise to more than 5,000° Celsius (about 9,000° Fahrenheit).

Harvesting Geothermal Energy: Heating and Cooling
Low-Temperature Geothermal Energy
Co-Produced Geothermal Energy
Geothermal Heat Pumps
Harvesting Geothermal Energy: Electricity
Dry-Steam Power Plants
Flash-Steam Power Plant
Binary Cycle Power Plants
Enhanced Geothermal Systems

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Nuclear Energy

Nuclear energy is a form of energy released from the nucleus, the core of atoms, made up of protons and neutrons. This source of energy can be produced in two ways: fission – when nuclei of atoms split into several parts or fusion – when nuclei fuse together. The nuclear energy harnessed around the world today to produce electricity is through nuclear fission, while technology to generate electricity from fusion is at the R&D phase. Nuclear power is a low-carbon source of energy, because unlike coal, oil or gas power plants, nuclear power plants practically do not produce CO2 during their operation. Nuclear reactors generate close to one-third of the world’s carbon free electricity and are crucial in meeting climate change goals.

Benefits of Nuclear Energy:

Protects national security
Fights climate change
Produces electricity reliably
Generates jobs
Protects our air
Boosts international development
Powers electric vehicles

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Biofuels & Bioenergy

Bioenergy is energy derived from biofuels. Biofuels are fuels produced directly or indirectly from organic material “biomass” including plant materials and animal waste. Overall, bioenergy covers approximately 10% of the total world energy demand. Modern bioenergy technologies include liquid biofuels produced from bagasse and other plants, bio-refineries, biogas produced through anaerobic digestion of residues, wood pellet heating systems, and other technologies.

Biomass feedstock’s are categorized as

First-generation biofuels: Food crops, such as corn, sugar cane, and maize for ethanol, and biodiesel
Second-generation biofuels: Cellulosic materials such as cotton, wood, grasses, and plant fibers
Third-generation biofuel: Algae

Bioenergy Technologies:

Advanced Algal Systems
Aviation Fuels
Bio product Production
CO2 Utilization and Storage
Conversion Technologies
Data, Modeling and Analysis
Feedstock Technologies
Systems Development and Integration
Waste-to-Energy

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Clean Energy

Clean energy is the energy which does not pollute the atmosphere creating little or no greenhouse gases. The term “clean” or “carbon-free” energy is used to refer to the electricity that is generated by facilities that do not directly emit greenhouse gases such as carbon dioxide during the generating process. Our world runs on the energy we produce. Clean energy production allows us to generate the energy we need without the greenhouse gas emissions and negative environmental effects that come with fossil fuels, in turn helping to reduce climate change.

Sources of Clean energy are

Sunlight
Wind
Water
Nuclear fission and
Geothermal heat

Modern Clean Tech Trends:

Low-carbon construction
Carbon capture and storage
Renewable energy storage
Hydrogen
Go zero-waste
Up cycling (circular waste management)

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Hydrogen Fuel Cell

A hydrogen fuel cell uses the chemical energy of hydrogen to produce electricity. It is a clean form of energy with electricity, heat and water being the only products and by-products. Fuel cells offer a variety of applications, from transportation to emergency back-up power, and can power systems as large as a power plant or as small as a laptop. Fuel cells provide advantages over traditional combustion-based technologies, including greater efficiencies and lower emissions. Since hydrogen fuel cells only emit water, there are no carbon dioxide emissions or other pollutants released into the atmosphere. Fuel cells are also quiet during operation as they have fewer moving parts than combustion technologies. Hydrogen fuel can be produced through several methods.

Thermal processes (Natural Gas reforming)
Electrolytic processes
Solar-driven processes
Biological processes

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Green Energy and Technology

Green energy is a subset of renewable energy and represents generation sources with the smallest environmental footprint – such as sunlight, wind, heat, and water. The name can also include low-impact hydroelectric sources and specific forms of biomass. Green energy creates no carbon emissions and has the lowest impact on the environment. Green energy can replace fossil fuels in all major areas of use including electricity, water heating, home appliances, and fuel for motor vehicles.

Green technology Innovations:

Wastewater treatment and water purification
Waste management and recycling
Waste-to-energy
Electric transport
Programmable thermostats
Self-sufficient buildings
Low carbon construction
Carbon capture and storage
Vertical farming
Composting
Green materials
Carbon tracking software

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Energy Conversion and Storage

Energy Conversion and Green Energy Storage present recent developments in renewable energy conversion and green energy storage. Storage of renewable energy requires low-cost technologies that have long lives – charging and discharging thousands of times – are safe and can store enough energy cost effectively to match demand.

Compressed air energy storage
Mechanical gravity energy storage
Lithium-Ion Battery Storage
Pumped Hydropower
Hydrogen
Advanced Rail Energy Storage
Flywheel Energy Storage
Liquid Air Energy Storage
Pumped Heat Electrical Storage
Redox Flow Batteries
Superconducting Magnetic Energy Storage
Methane

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Smart Materials

Smart Materials are the ones that can adapt to their environment and change their properties depending on environmental conditions. These materials are characterized by dynamic properties and response to different stimuli, such as light, heat, electricity, or humidity.

Smart Materials can optimize resource use and promote a circular economy. By adapting to environmental conditions, smart materials can be reused and recycled, reducing environmental impact, and increasing sustainability.

Smart materials can be used in different types of industries, such as the electronics and construction industries. Some of the most popular smart materials have heat-resistant, self-curing and self-assembling properties. These materials can be used to manufacture strong, efficient, and sustainable products. Circular economy and smart materials are a powerful combination that can help create a more sustainable future.

Types of Smart Materials:

Piezoelectric materials
Shape memory materials
Chromoactive materials
Magnetorheological materials
Photoactive materials
Hydrogels
Electroactive Polymers
Bi-Component Fibers

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Sustainable Finance

Sustainable finance refers to the process of taking environmental, social and governance (ESG) considerations into account when making investment decisions in the financial sector, leading to more long-term investments in sustainable economic activities and projects. The European Union strongly supports the transition to a low-carbon, more resource-efficient and sustainable economy and has been at the forefront of efforts to build a financial system that supports sustainable growth. Sustainable finance is understood as finance to support economic growth while reducing pressures on the environment and taking into account social and governance aspects.

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Sustainable Agricultural Systems and Technology

Sustainable agriculture refers to farming methods that are friendly to the environment and allow for the crops or livestock husbandry without causing harm to human or natural systems. Sustainable agriculture forms the integral part of sustainable development concept. Alternate land use systems, conservation agriculture, regenerative agriculture, organic farming, precision farming, integrated nutrient management, information and communication technologies, mixed farming, multiple cropping, and crop rotation are all elements of sustainable agriculture.

Green technologies and techniques in agriculture:

Transformation in agricultural systems
Agricultural Biotechnologies
Economy and food security
Emergence of renewable energies
Renewable energies in agriculture
Farms with sustainability
Energy management in agricultural areas
Renewable innovation and applications
Environmental quality of resources
Smart energy agriculture networks
Sustainable agricultural systems
Sustainable farming systems
Sustainable food systems

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Renewable and Recyclable Energy

Renewable and recyclable energy (nuclear power, wind power and solar power) could help decouple fossil fuel from economic growth; these energy sources have costs and benefits economically, socially, and environmentally, and in terms of their contribution to energy security. Energy recycling is the recovery of energy that would normally be wasted in industrial processes by flaring, exhausting to the atmosphere or operating low efficiency equipment, and converting it into electricity or thermal energy (steam or heated water).

Recycling industrial waste
Plastic Recycling
Agriculture Waste Recycling
Waste plastic pyrolysis to fuel oil
Combined Heat and Power
Waste Water Recycling
Paper Recycling
E-Waste Recycling and Management
Solid Waste Management
Chemical Waste Recovery
Food Waste Recycling

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Energy Policy

Economies of scale and innovation are already resulting in renewable energies becoming the most sustainable solution environmentally but also economically in terms of low costs for keeping energy prices at affordable levels. With global warming, habitat destruction, poverty and many other socio-environmental issues becoming more pressing, it is clear that we need to invest in more sustainable development practices. Each resource needs to be developed as a way to stabilize and reduce back oxide emissions. There are numerous energy guidelines on an international scale on the subject of energy exploration, manufacturing, and consumption, starting from commodities organizations to automobile manufacturers to wind and star manufacturers and commercial enterprise associations. Sustainable development mainly covers the use of renewable energy, energy security, energy pricing, energy policy, renewable energy applications and smart grid technologies.

Energy, exergy and environment policies and management
Carbon tax
Energy and carbon savings incentive
Energy and environment security
Environmental issues and the public
Enviroeconomics and exergoeconomics
Energy and Exergy efficiency
Sustainable energy education
Sustainable energy awareness, acceptance and take-up
International cooperation
Artificial intelligence applications in energy systems
Desining and construction management
Green energy economy and governance
Risk management in energy and building system

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Nano Energy & Technology

Nanotechnology makes a huge revolution in the size and design of renewable energy devices utilized for energy conversion and storage, environmental monitoring, as well as green engineering of environmental friendly materials. It is shown that, nanomaterial’s play a significant role on the human life, by providing a cheap and clean energy which is now becomes a global industry. Nano technological products, processes and applications are expected to contribute significantly to environmental and climate protection by saving raw materials, energy and water as well as by reducing greenhouse gases and hazardous wastes. Using nanomaterials therefore promises certain environmental benefits and sustainability effects.

Green Nanotechnology
Sustainable Energy Production
Nanomaterials for Energy Conversion & Storage
Nanomaterials for Hydrogen, Fuel Cells & Thermal Energy
Treatment & Remediation

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Biopolymers and Bioplastics from Renewable Sources

Biopolymers are natural polymers produced by the cells of living organisms. They can be sustainable, carbon neutral and are always renewable because they are made from plant or animal materials which can be grown indefinite. Renewable resources are used increasingly in the production of polymers. Life-cycle assessment can be used to quantify the environmental benefits of sustainable polymers. Bio-based polymers can also be synthesized from biomass. Biopolymers are new generations of materials that are still in development and that have attracted attention as possible replacement‐based materials of conventional plastics due to an increased interest in sustainable development. Bioplastics are the plastic materials produced from renewable biomass sources, such as vegetable fats and oils, corn starch, straw, woodchips, sawdust, recycled food waste, etc. Bioplastic production significantly reduces greenhouse gas emissions and decreases non-renewable energy consumption. Renewable bio-based polymers are one of the effective answers that the bio economy offers to solve the environmental emergency connected to plastics and more specifically fossil-based plastics.

Biopolymers from diverse origin:

Vegetable origin (starches, celluloses, pectin’s, chitosan, zein, etc.)
Animal origin (casein, whey protein, and gelatin)
Microbial products (polyhydroxybutyrate and polyhydroxyvalerate)
Natural origin (polylactic acid).

Most Common types of Bioplastics:

Starch-Based (corn starch)
Cellulose-Based (cellulose esters and cellulose derivatives)
Protein-Based (wheat gluten, casein and milk)
Bio-derived Polyethylene (raw agricultural materials like sugarcane and corn)
Aliphatic Polyesters (PLA, PHB, PGA)

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Climate Change and Recycling

Climate Change refers to long-term shifts in temperatures and weather patterns. These shifts may be natural, such as through variations in the solar cycle. Climate change threatens people with food and water scarcity, increased flooding, extreme heat, more disease, and economic loss. Climate change can be mitigated by reducing greenhouse gas emissions and by enhancing sinks that absorb greenhouse gases from the atmosphere renewable energy is the key to limiting climate change. Reducing energy demand is another major aspect of reducing emissions.

Manifestation of Climatic Change
Causes and Effects of Climate Change
CO2 Capture and Sequestration
Risks of Climate Change
Climatology
Climate Change Challenges
Endangered Species and Forestry
Regenerative Agriculture to Reverse Climate Change
Climate Changing Cloud Heights
Earth Science and Climate Change Policies

Recycling:

Recycling is the process of converting waste products into reusable materials. Typical materials that are recycled include iron and steel scrap, aluminum cans, glass bottles, paper, wood, and plastics. The materials reused in recycling serve as substitutes for raw materials obtained from such increasingly scarce natural resources as petroleum, natural gas, coal, mineral ores, and trees. Recycling can help reduce the quantities of solid waste deposited in landfills, which have become increasingly expensive. Recycling also reduces the pollution of air, water, and land resulting from waste disposal.

There are two broad types of recycling operations: internal and external.

Internal recycling is the reuse in a manufacturing process of materials that are a waste product of that process.
External recycling is the reclaiming of materials from a product that has been worn out or rendered obsolete.

Waste Management Techniques
E-Waste Recycling and Management
Solid Waste Management
Waste Water Recycling
Plastic & Paper Recycling
Industrial Waste Recycling
Chemical Waste Recovery
Food Waste Recycling
Agriculture Waste Recycling
Recycling Market
Thermal Waste Recovery
Construction Waste Management
Textile Recycling
Glass Recycling
Home-waste management
Recycling: Eco-balance

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Non-renewable Energy and Resources

Non-renewable Energy is a source of energy that will eventually run out. The resources which cannot be immediately replaced once they are depleted are called non-renewable resources. Non-renewable energy sources can be used for all kinds of things. Over 70% of the energy used in industrial processes comes from non-renewable sources, while fossil fuels are also used for many household purposes. Non-renewable resources include:

Fossil fuels
Coal
Petroleum
Natural gas
Rare minerals typically found in meteorites

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Smart Grid

The digital technology that allows for two-way communication between the utility and its customers, and the sensing along the transmission lines is what makes the grid smart. The Smart Grid represents an unprecedented opportunity to move the energy industry into a new era of reliability, availability, and efficiency that will contribute to our economic and environmental health. Smart Grid is a way to address an aging energy infrastructure that needs to be upgraded or replaced. It’s a way to address energy efficiency, to bring increased awareness to consumers about the connection between electricity use and the environment.

Smart Sensors & Advanced Metering Infrastructure
Impact of Smart Grid on Energy Resources
Smart Grids Technologies
Smart Grids Applications & Challenges

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Global Warming

Global Warming is the long-term warming of the planet’s overall temperature. Though this warming trend has been going on for a long time, its pace has significantly increased in the last hundred years due to the burning of fossil fuels. Fossil fuels include coal, oil, and natural gas, and burning them causes what is known as the “greenhouse effect” in Earth’s atmosphere. Global warming has presented another issue called climate change.

Greenhouse gasses are

Carbon Dioxide
Chlorofluorocarbons
Water vapor
Methane
Nitrous oxide

Causes for Global Warming are:

Greenhouse Gases
Acid rains
Reduced agricultural yields
Volcanic Activity
Declining water supplies

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Pollution Control

Pollution is the introduction of harmful materials into the environment. These harmful materials are called pollutants. Pollution control is the process of reducing or eliminating the release of pollutants into the environment. It is regulated by various environmental agencies which establish pollutant discharge limits for air, water, and land.

Waste management and clean-up
Recycling or disposal

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Waste and Residue Management

Waste management is the strategy an organization uses to dispose, reduce, reuse, and prevent waste. Residual waste is nonhazardous industrial waste. It includes waste material (solid, liquid or gas) produced by industrial, mining and agricultural operations. It excludes certain coal mining wastes and wastes from normal farming activities.

Waste disposal methods:

Recycling
Composting
Incineration
Landfills
Bioremediation
Waste to energy
Waste minimization

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Waste-to-Energy

Waste-to-Energy is a technologically advanced means of waste disposal that is widely recognized for reducing greenhouse gases particularly methane by eliminating emissions from landfills. Waste-to-Energy takes non-hazardous waste otherwise destined for landfill and combusts it, generating steam for electricity production. Waste-to-Energy technologies consist of any waste treatment process that creates energy in the form of electricity, heat or transport fuels (e.g. diesel) from a waste source.

Waste to Energy processes are

Incineration
Gasification
Pyrolysis
Anaerobic digestion
Landfill gas recovery

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Environmental Impact and Sustainability

Environmental Impact is the effect of human activity on the environment in the form of creating environmental imbalance. Environmental Impact Assessment (EIA) is a tool used to assess the significant effects of a project or development proposal on the environment. Environmental Sustainability is the responsibility to conserve natural resources and protect global ecosystems to support health and wellbeing, now and in the future.

Some of the most common environmental impacts are:

Environmental and climate change
Detection of hazardous substances
Dynamics and environmental sustainability
Gas emissions
Sustainable energy and environment
Waste and residue management
Ecosystem management
Sustainable management of resources
Hydrology and ecosystems
Impact and ecological engineering
Pollution and waste treatment
Global warming
Smart sustainable cities

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Power and Energy Engineering

Power Engineering deals with generation, transmission and distribution of electric power. Energy Engineering is also referred as Energy Technology as it handles conversion, transfer, production, distribution and use of energy. It involves various natural resources such as fossil fuels or petroleum and tries to increase the usage of renewable or sustainable energy sources such as wind, solar and wave power, biomass, hydroelectricity, or nuclear power.

Electricity Networks of the Future
Energy Storage Technologies and Devices
Power and Energy Generation
Energy Transmission and Distribution
Power Systems and Automation
Fault monitoring and Predictive Maintenance

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European Congress on

Renewable Energy and Sustainable Development

November 16-17, 2023H10 Roma Città, Rome, Italy

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Renewable Energy & Resources

Renewable Energy & Resources

Sustainable Development

Sustainable Development

Global Industrial Processes and Sustainable Development:

Global Industrial Processes and Sustainable Development:

Solar Energy

Solar Energy

Types of Solar Energy:

Wind Energy

Wind Energy

Hydro Energy

Hydro Energy

Tidal Energy

Tidal Energy

Geothermal Energy

Geothermal Energy

Nuclear Energy

Nuclear Energy

Biofuels & Bioenergy

Biofuels & Bioenergy

Clean Energy

Clean Energy

Hydrogen Fuel Cell

Hydrogen Fuel Cell

Green Energy and Technology

Green Energy and Technology

Energy Conversion and Storage

Energy Conversion and Storage

Smart Materials

Smart Materials

Sustainable Finance

Sustainable Finance

Sustainable Agricultural Systems and Technology

Sustainable Agricultural Systems and Technology

Renewable and Recyclable Energy

Renewable and Recyclable Energy

Energy Policy

Energy Policy

Nano Energy & Technology

Nano Energy & Technology

Biopolymers and Bioplastics from Renewable Sources

Biopolymers and Bioplastics from Renewable Sources

Climate Change and Recycling

Climate Change and Recycling

Non-renewable Energy and Resources

Non-renewable Energy and Resources

Smart Grid

Smart Grid

Global Warming

Global Warming

Pollution Control

Pollution Control

Waste and Residue Management

Waste and Residue Management

Waste-to-Energy

Waste-to-Energy

Environmental Impact and Sustainability

Environmental Impact and Sustainability

Power and Energy Engineering

Power and Energy Engineering

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